Pluchino Stefano, Gritti Angela, Blezer Erwin, Amadio Stefano, Brambilla Elena, Borsellino Giovanna, Cossetti Chiara, Del Carro Ubaldo, Comi Giancarlo, 't Hart Bert, Vescovi Angelo, Martino Gianvito
Neuroimmunology Unit, San Raffaele Scientific Institute, Milan, Italy.
Ann Neurol. 2009 Sep;66(3):343-54. doi: 10.1002/ana.21745.
Transplanted neural stem/precursor cells (NPCs) display peculiar therapeutic plasticity in vivo. Although the replacement of cells was first expected as the prime therapeutic mechanism of stem cells in regenerative medicine, it is now clear that transplanted NPCs simultaneously instruct several therapeutic mechanisms, among which replacement of cells might not necessarily prevail. A comprehensive understanding of the mechanism(s) by which NPCs exert their therapeutic plasticity is lacking. This study was designed as a preclinical approach to test the feasibility of human NPC transplantation in an outbreed nonhuman primate experimental autoimmune encephalomyelitis (EAE) model approximating the clinical and complex neuropathological situation of human multiple sclerosis (MS) more closely than EAE in the standard laboratory rodent.
We examined the safety and efficacy of the intravenous (IV) and intrathecal (IT) administration of human NPCs in common marmosets affected by human myelin oligodendrocyte glycoprotein 1-125-induced EAE. Treatment commenced upon the occurrence of detectable brain lesions on a 4.7T spectrometer.
EAE marmosets injected IV or IT with NPCs accumulated lower disability and displayed increased survival, as compared with sham-treated controls. Transplanted NPCs persisted within the host central nervous system (CNS), but were also found in draining lymph nodes, for up to 3 months after transplantation and exhibited remarkable immune regulatory capacity in vitro.
Herein, we provide the first evidence that human CNS stem cells ameliorate EAE in nonhuman primates without overt side effects. Immune regulation (rather than neural differentiation) is suggested as the major putative mechanism by which NPCs ameliorate EAE in vivo. Our findings represent a critical step toward the clinical use of human NPCs in MS.
移植的神经干细胞/前体细胞(NPCs)在体内表现出独特的治疗可塑性。尽管细胞替代最初被认为是干细胞在再生医学中的主要治疗机制,但现在很清楚,移植的NPCs同时引发多种治疗机制,其中细胞替代不一定占主导地位。目前尚缺乏对NPCs发挥其治疗可塑性机制的全面了解。本研究设计为一种临床前方法,以测试在一种远交非人类灵长类动物实验性自身免疫性脑脊髓炎(EAE)模型中进行人NPC移植的可行性,该模型比标准实验室啮齿动物的EAE更接近人类多发性硬化症(MS)的临床和复杂神经病理学情况。
我们在受人类髓鞘少突胶质细胞糖蛋白1 - 125诱导的EAE影响的普通狨猴中,检查了静脉内(IV)和鞘内(IT)注射人NPCs的安全性和有效性。在4.7T光谱仪上出现可检测到的脑损伤时开始治疗。
与假手术对照组相比,静脉或鞘内注射NPCs的EAE狨猴残疾程度较低,存活率提高。移植的NPCs在宿主中枢神经系统(CNS)中持续存在,但在移植后长达3个月的引流淋巴结中也被发现,并在体外表现出显著的免疫调节能力。
在此,我们提供了首个证据,即人中枢神经系统干细胞可改善非人类灵长类动物的EAE且无明显副作用。免疫调节(而非神经分化)被认为是NPCs在体内改善EAE的主要推定机制。我们的研究结果代表了人NPCs在MS临床应用方面的关键一步。
